CAVES AND KARST Research in Speleology Volume 10. No.5 September/October 19rJ8 Figure 1. The twil ight moth, TripllOsa hacsitata (X2). THE TWILIGHT MOTH, TRIPHOSA HAESITAT A, (LEPIDOPTERA: GEOMETRIDAE) FROM CALIFORNIA AND NEVADA CAVES by RICHARD EARL GRAHAM,· Cave Research AJJociateJ Introduction The twilight moth, Triphosa haesitata, ( Figure 1) is an important inhabitant of cave entrances in Nevada and California. This tan ro dark brown morh is relatively common and can be found resting on open surfaces so that the species can be easily identified and studied in detail. A species account based on studies in California caves follows and, where possible, comparisons are made ro cave-related triphos ids in Nevada, Europe and Asia. An annotated checklist is given at the end of this reporr. Status of cave-related moths Since moths are not usually regarded as cave inhabitants in the strict se nse, cave-related moths have not been given attention relative ro their actual importance. There is no com­ prehensive review or definitive statement of the nature of the relationship between moths and the cave environment. Yet, even a cursory search of the cave literature reveals an abundance of information about a rather large number of cave-inhabiting moths (WOLF, 1934-1938; VAN DEL, 1965; and T ERCAFS, 1960 ) . • Department of Zoology and Physiology, Rutgers University, Newark, New Jersey 41 CAVES AND KARST CAVES AND KARST CAVES AND KARST is a publication of Cave Research Associates. Subscriptions are available for $2.50 per year (.six issues) or $6.00 for Volumes 10 through 12. Mid-year subscriptions receive the earlier numbers of the volume. Correspondence, contributions, and subscriptions should be addressed to: CAVE RESEARCH ASSOCIATES, 3842 Brookdale Blvd., Castro Valley, Calif. 94546 Editor: Arthur L. Lange Associate Editor: James G. Day Editors: Neely H. Bostick, R. deSaussure, J . F. Quinlan, Sylvia F. Graham © Copyright 1968, Cave Research Associates A major problem is the inability ro explain the presence of moths in caves. Since Jea nnel ( 1926) posed this question, a variety of arrempts have been made at answers. Tercafs (1960) has critically reviewed and refuted prior Iiterarure; he concluded that the solution required experimentation and more knowledge of the life hisrory of each moth. Litrle has been published on the life hisrory of TI'ipbosa bClesitata. The following works were consulted but they offer no pertinent information applicable ro this srudy (FORBES, 1948; JONES, 1951; and MCGUFFIN, 1958 ). Distribution and conditions of caves containing Triphosa Triphosids are primarily N orth Temperate and Holarctic in distribution (Figure 2.). Two species, T. clttbitatcI and T. suba1lclitata, frequent English and European mainland caves (HAZELTON and GLENN IE, 1954; WOLF, 1934- 1938; and others). The former species is repon ed from Japanese caves (TORII, 1953a, 1953b) ; and T. baesitata, from western United States caves (GRAHAM, 1962 and 1968). The considerable ropographic, climatic and biOtic di versity throughout their extensive range is an imponant consideration. In California and N evada (Figure 3), great differences are found within the caves themselves and between cave environs of known T. baesitattl rOOsts. These caves range fr om the humid, maritime Santa Cruz Mountains of the so-called "Redwood Transition Zone" northwa rd ro the more inland higher elevation forests of the Trinity Mountains of the Oregonian Bioti c Province. To the east they roost in caves in the semi-arid foothills of Shas ta County and the northern end of the Sierra Nevada of Plumas County. Twilight moths have not been found in the extensive Mother Lode cave region ro the southeast, although Figure 2. Te ntati ve range of the genus TriJl1108(1 (stippled); Eurasian dis­ tribution afte r SEITZ (1914) and North American, from various sources (see Acknow ledgements). Know n areas where triphosids enter caves (black) include western North America, England, Europe and western Asia and Japa n. 42 VOLUME 10, NO.5 they are known to inhabit the epigeic portion of this area. Farther south they again occ upy caves from the Alpine Zone down to Lower Sonoran Zone of the Mojave Desert. To the east and north this moth frequents caves in the mountains of N evada. T hese roosts vary from 100 to 3300 meters above sea level. They occur in five major landform and biOt ic provinces, and encompass a great variety of local climatic conditions (See EARDLEY, 1951 and MUNZ & K ECK, 1959) . Since conditions wi thin the cave entrances reflect this diversity, the twilight moth must have a wide ecological tolerance for ambient cave climates. Abundance and duration in caves Between July 1952 and October 1966, twilight mOth colonies were observed 33 times from 22 caves in California and Nevada. COUntS of visible populations during 21 visits to California caves range between 1 and 65 individuals with a mean of 26 (Table 1). These visits were not sys tematic, so that no caves known to house twi li ght moths were inspected in February , March and May, but mOths were seen in caves during the Other nine months. The data on monthly calculations of abundance are tenuous and incomplete; thus far, however, they show no clear seasonal pattern as might be expected if hibernation were the only factor involved in cave occupation. In Europe, cave-i nhabiting triphos ids are said to be year-round (JEAN NEL, 1926), but Others argue that they hibernate during winters (TERCAFS, 1960 and TUCK ER, 1964). Related to the general HAESITATA abundance of moths in caves is the question of how long individuals remain in caves. Tucker (1964 and " DRiP CAVE 1966), using a mark-recap­ .. /< ,..... " SAMWEL CAVE ture technique, found a reg­ ':)\ FOREST HALL CiTY CAVE / ular turnover for individ­ :.:.;:.;:: GLEN CAVE SODA SPRiNGS GNOME LAKE CAVERN uals of presumably hiber­ :; ':'\;: ".-CAVE .. nating English cave mOths. KLOPP ENBERG SNOW CAVE~ Without marking mOths, I CAVERNS was unable to detect indi­ vidual or cyclic activity. When moths were under regular observation night and day, both sequentially and on scattered occasions, changes were few. At Sam­ wei Cave, Shas ta County, KiNG'S CAVERN .... moths under almost con­ JORDAN CAVE~ ~ tinual observation for six WHiTE CHiEF CAVES weeks in June and July 1960 showed no changes, except for a single mOth ~ ,:: ;.. , MiTCHELCS that disappeared during the : .. ::: ..: . :: :<. ... : .:: . CAVERNS first week. ::,':..... :. , ', ", .. ; ~ .::': .' .: .: .;.... ': ,:':.:" With the available in­ .' :': '::.': :::.-:.: .... ', ','; : ',: .... ::.: ... formation it would be haz­ ardous to generalize on these aspects of moth cave ..••.. ».:,\ .. ;.:.: .:.;.\j..::.'~ ... :r. ---_.1 residence without more de­ ", .:.>, ', :,,' ',:. ::.'.::: : . .... tailed data from each of the widely different cave Figure 3 . California and N evad a cave sites known to regions. be twilight moth roosts. 43 CAVES AND KARST J A,' FEU MAR APH MAY JUN JIJL AUG SEP OCT NOV DEC n 1 nc I nc I 1 nc 1 1 6 3 5 2 2 Range 6 4 I1C nc nc nc 1 5 15 2-31 1-26 1-25 30-65 4-7 :t 64 nc nc I1C nc 15 15 18 11 13 47 5 TABLE 1. Counts of v isible popul ations of Tri"llOsa haesitata in California caves betw een July 1952 and October 1966. The statistics are the following; 1" number of counts (Ile = no count); rallge, number of individual moths; and x, the average number of moths per month in caves. These data are based on an informal sampling. Sex ratio Samples of collected moths were sexed (see Annotated Checklist). This check re­ vealed approximately equal numbers of males and females from several caves. Orientation Banta (1907) describes orientation behavior in the cave moth Scoliopteryx libat·ryx­ both in the cave and laboratory - as showing a preference to orient towards the light source. No such habit was seen for the twilight moth, (see Figure 1 of GRAHAM, 1968): moths were found to face all directions. In the only exception (Figure 4), individuals about the periphery of the contact-cluster all faced distinctly towards the center of the cluster. The biological meaning of this orientation is unknown, bur may be related to some aspect of the clustering behavior. Zonation The twilight moth roosts in a particular portion of the cave entrance. In the Santa Cruz caves, the roosts tend to be especially compact and related to light intensity (GRAHAM, 1968). In California caves, moths were counted and mapped with reference to the relative light zones on 13 different occasions. Of 230 moths none occurred in Zone 1 (the cave mouth), but 97, or 42 % were found in Outer Twilight (Zone 2); 121, or 53 % in Mid Twil ight (Zone 3); and 12, or 5 % were isolated from the main colonies in Deep Twi­ light (Zone 4) near the light/dark boundary (Figure 5). A typical example of deep moths is shown in Figure 6. o 5 10 eM Figure 4 . Contact cluster of tw ilight moths (redrawn from Figure 3, GRAHAM, 1968) showing the orientation of peripheral individuals towards the center of the cluster. 44 VO LUME 10, NO.5 In each case in which isolated moths were found in the Deep Twi­ light Zone, the moths were situated 60 on dimly lighted SpOts in an other­ V) wise dark area. Such weak shafts of 50 • =0- light may penerrate well into seem­ C> ingly aphotic areas for short inter­ ::E / 40 • vals of time. Presumably moths 0- arrive at the cave entrance during =~ darkness, and those near the cave -' 30 mouth shift deeper into the cave as ~ ambient light intensity increases. 0- 0- 20 Perhaps in their search for more op­ z: timal light levels for roosting some .... <..> 10 individuals srray deep into the cave. a:: In every case in which I have ex­ .... amined deep moths they had visual 0 ."""i !- contact with the entrance during the 2 3 4 5 peak of the diurnal photic tide.
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